Systems and methods for anchoring medical devices

ABSTRACT

Some embodiments of a medical device anchor system include an anchor device that secures a medical instrument (such as a catheter or the like) in place relative to a skin penetration point using subcutaneous anchors.

TECHNICAL FIELD

This document relates to devices, systems, and methods for securing the position of a catheter or another medical instrument, for example, at a skin opening.

BACKGROUND

Venous, arterial, and body fluid catheters are commonly used by physicians. For example, such catheters may be used to gain access to the vascular system for dialysis, for introducing pharmaceutical agents, for nutrition or fluids, for hemodynamic monitoring, and for blood draws. Alternatively, catheters can be used for drainage of fluid collections and to treat infection. Alternatively, catheters can contain electrical leads for neuro-stimulation, cardiac pacing, and the like. Following introduction into the patient, the catheter is secured to the patient. In many instances, the catheter is commonly secured to the patient using an adhesive tape on the skin or by suturing a catheter hub to the patient's skin. In other circumstances, the catheter may be secured to the patient using a subcutaneous anchor mechanism (such as an anchor sleeve equipped with anchors that are deployed using an external actuator handle or a separate delivery device). In many cases, the medical practitioner will make efforts to clean the skin area around the catheter insertion site for purposes of a patient's comfort, safety, and improved visualization of the catheter insertion site after the catheter is installed.

SUMMARY

Some embodiments of a medical device anchor system include an anchor device that provides an adhesive coupling with a medical instrument (such as a catheter or the like that is optionally equipped with suture wings) and furthermore secures the instrument in place relative to a skin penetration point. For example, the medical anchor device can be equipped with a flexible fabric portion that is configured to adhesively attach to a shaft of a hub of a catheter while the medical anchor device also provides subcutaneous anchor mechanisms deployable through the skin penetration point that is already occupied by the catheter, thereby reducing or eliminating the need for installing sutures through the suture wings and the patient's skin. Optionally, in some embodiments the anchor device can be adjusted to a folded configuration that orients the tines of the subcutaneous anchors in a generally side-by-side configuration to facilitate insertion of the anchors through the skin penetration point. Such a configuration may allow the anchor device to be installed after medical instrument is already in place without the need for a second penetration point for the anchor device. In particular embodiments, the anchor device may be configured to simplify the use of the anchor device, make the anchor device more adaptable to use with medical instruments of different sizes, and to facilitate the maintenance and cleaning of the skin tissue at and around the skin penetration point.

In particular embodiments, an anchor device for securing the position of a medical instrument may include a retainer body. The retainer body can include a first body portion that is hingedly coupled to a second body portion about a longitudinal folding region. Also, the anchor device may include one or more flexible adhesive strips mounted to the retainer body. The one or more flexible adhesive strips can be configured to adhesively attach with one or more corresponding exterior surfaces of a medical instrument. The anchor device may further include first and second anchors that extend distally from a distal end of the retainer body. Each anchor may include a flexible tine that is deployable in a subcutaneous region to secure the retainer body relative to a penetration point. The first anchor may be coupled to the first body portion, and the second anchor may be coupled to the second body portion. The first body portion of the retainer body can be hingedly movable relative to the second body portion about the longitudinal folding region so that the first and second anchors are adjustable from a first configuration in which the flexible tines extend outwardly away from one another to a second configuration in which the flexible tines extend generally in the same direction.

Some embodiments of an anchor device may include a retainer body and first and second flexible adhesive strips. The retainer body may include a first body portion that is pivotably coupled to a second body portion about a longitudinal fold axis. The first and second flexible adhesive strips may be configured to mate with an external structure of a medical instrument to adhesively couple the medical instrument to the retainer body. The first flexible adhesive strip may be mounted to the first body portion of the retainer body, and the second flexible adhesive strip may be mounted to the second body portion of the retainer body. The anchor device can also include first and second anchors that extend distally from a distal end of the retainer body. Each anchor may include a flexible tine that is deployable in a subcutaneous region to secure the retainer body relative to a penetration point. The first anchor may be coupled to the first body portion, and the second anchor may be coupled to the second body portion. The first body portion of the retainer body may be pivotable relative to the second body portion about the longitudinal fold axis so that the first and second anchors are adjustable from a first configuration in which the flexible tines extend outwardly away from one another to a second configuration in which the flexible tines extend generally in the same direction.

Other embodiments described herein include a system for securing the position of a medical instrument. The system may include a medical instrument comprising a distal portion configured to extend through a skin penetration point and into a body, and an external portion configured to reside outside the body when the distal portion extends through the skin penetration point. The system may also include an anchor device. The anchor device may comprise a retainer body including a first body portion that is pivotably coupled to a second body portion. The anchor device may also comprise one or more flexible adhesive strips mounted to the retainer body. The one or more flexible adhesive strips may be configured to adhesively attach with one or more surfaces of the external portion of the medical instrument. The anchor device may further comprise first and second anchors that extend distally from a distal end of the retainer body. Each anchor may include a flexible tine that is deployable through the skin penetration point occupied by the medical instrument and into a subcutaneous region to secure the retainer body relative to the skin penetration point. The first anchor may be coupled to the first body portion, and the second anchor may be coupled to the second body portion. The first body portion of the retainer body may be pivotable relative to the second body portion so that the first and second anchors are adjustable from one another to a removal configuration in which the flexible tines extend generally in the same direction.

Some embodiments described herein include a method of using a medical anchor system. The method may include advancing an anchor device toward a skin penetration point while the anchor device is in a folded condition so that a plurality of subcutaneous tines of the anchor device are generally adjacent to each other and oriented to extend in substantially the same direction. The method may also include inserting the subcutaneous tines through the skin penetration point and into a subcutaneous region adjacent to an underside of a skin layer while the anchor device is in the folded condition. Each of the subcutaneous tines may have a shape which terminates at a tip of a free end during insertion through the skin penetration point. The method may further include adjusting the anchor device to a non-folded condition after the subcutaneous tines are inserted into the subcutaneous layer so that the subcutaneous tines are in an anchored position in which the free ends of the subcutaneous tines extend generally away from one another. Also, the method may include adhesively securing a medical instrument to the anchor device after the subcutaneous tines are adjusted to the anchored position in the subcutaneous region. The operation of adhesively securing may include coupling one or more flexible adhesive members of the anchor device with one or more exterior surfaces of the medical instrument.

These and other embodiments may provide one or more of the following advantages. First, some embodiments of an anchor system can retain a medical instrument in a desired position relative to a skin penetration point without necessarily requiring sutures or skin adhesives. Second, particular embodiments of the anchor device may be readily adaptable to use with catheters or other medical instruments of different sizes, while also securing the catheter or medical instrument to a skin penetration point in a manner that facilitates improved inspection and cleaning of the skin tissue at and around the skin penetration point. For example, some of these particular embodiments of the anchor device can provide a capless design in which an adhesive fabric of the anchor device adhesively couples the anchor device to an external portion of the catheter or medical instrument without the need for an attachable cap device, thereby simplifying the process for a practitioner to couple the anchor device to the catheter or medical instrument. As another example, some of these particular embodiments include a tear strip in the adhesive fabric to permit a practitioner to decouple the catheter or medical device from the anchor device. Third, in some embodiments, the anchor device may be adjusted between a folded configuration and a non-folded configuration so that the subcutaneous anchors are arranged side-by-side and extend in generally the same direction during both installation through and removal from the skin penetration point. Fourth, in some embodiments, the anchor device can be installed in accordance with a technique that reduces or eliminates the need to shift the subcutaneous tines to or from a flexed or stressed configuration. Thus, in these embodiments, the subcutaneous anchors may be readily installed and removed from the skin penetration point without the need for a separate external actuator or delivery device. Fifth, in some embodiments, the configuration of the anchor device can simplify the process of installing a medical instrument onto the anchor device and removing the medical instrument from the anchor device. Sixth, in some embodiments, the anchor device can be configured to be usable with a variety of styles and sizes of medical instruments. Seventh, in some embodiments, the anchor device can enable a hub of a catheter or other medical instrument to be positioned in close proximity to the skin penetration point.

The details of one or more embodiments of the invention are set forth in the accompanying drawings and the description below. Other features, objects, and advantages of the invention will be apparent from the description and drawings, and from the claims.

DESCRIPTION OF DRAWINGS

FIG. 1 is a perspective view of an anchor device with a portion of the device located in a subcutaneous region, in accordance with some embodiments.

FIGS. 2A-2C are perspective, side, and rear views, respectively, of the anchor device of FIG. 1.

FIGS. 3A-3B are perspective and top views, respectively, of the anchor device of FIG. 1 in a folded condition, in accordance with some embodiments.

FIGS. 4-7A are perspective views of an anchor system, including the anchor device of FIG. 1, for use in securing the position of a medical instrument.

FIG. 7B is a rear view of the anchor system, including the anchor device of FIG. 1.

FIG. 8 is a perspective view of the anchor system, including the anchor device of FIG. 1.

FIG. 9 is a perspective view of an anchor device with a portion of the device located in a subcutaneous region, in accordance with some embodiments.

FIGS. 10A-C are perspective, side, and rear views, respectively, of the anchor device of FIG. 9.

FIGS. 11A-B are perspective and top views, respectively, of the anchor device of FIG. 9 in a folded condition, in accordance with some embodiments.

FIGS. 12-16 are perspective views of an anchor system, including the anchor device of FIG. 9, for use in securing the position of a medical instrument.

FIGS. 17A-17B are perspective and side views, respectively, of an anchor device in accordance with some alternative embodiments.

Like reference symbols in the various drawings indicate like elements.

DETAILED DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS

Referring to FIG. 1, some embodiments of a medical device anchor system 104 include an anchor device 100 that adhesively attaches to a medical instrument 102 and furthermore secures the medical instrument 102 in an operative position relative to a portion of skin 30. The medical instrument 102 can be adhesively coupled to the anchor device 100 after the medical instrument 102 using, for example, a flexible fabric portion 170 having an adhesive layer thereon. The anchor device 100, in turn, can be coupled to the portion of skin 30 using one or more subcutaneous members 145 a-b. In this manner, the anchor device 100 can act as an intermediary member to cause the retention of the medical instrument 102 in a desired position with respect to the skin 30. The example embodiment of FIG. 1 can include the medial instrument 102 (e.g., a central venous catheter 102) inserted through a percutaneous opening formed in the skin (e.g., penetration point 32), proceeding to the underside of the skin 30, and into a vein 40 to provide vascular access for delivering medications, withdrawing fluids, or providing minimally invasive access into a patient.

In this example, the anchor device 100 can generally include a retainer body 110, adhesive fabric 170, and one or more anchors 140 a-b. The adhesive fabric 170 extends proximally from a proximal end of the retainer body 110. The one or more anchors 140 a-b extend distally from a distal end of the retainer body 110. As described further below, the anchor device 100 can be configured to couple with the medical instrument 102. The one or more anchors 140 a-b can be configured for deployment through a skin penetration point 32 and into a subcutaneous layer 34, so as to releasably retain the anchor device 100 with respect to the skin 30. For example, the anchor device 100 can include the one or more anchors 140 a and 140 b that extend distally from the retainer body 110 so as to penetrate through the same skin penetration point while the retainer body 110 (and the adhesive fabric 170 mounted thereto) remain external to the skin penetration point 32. In some embodiments, the skin penetration point 32 may be defined by a small incision, a puncture, or the like through the dermal layers 36.

The anchors 140 a-b can include subcutaneous tines 145 a-b that, after insertion, reside in the subcutaneous region 34 (e.g., a region immediately under the skin 30 that may comprise a fatty tissue layer) so as to secure the position of the anchor device—and the medical instrument 102 retained therein—relative to the penetration point 32. When the tines 145 a-b are deployed in the subcutaneous region 34, the anchor device 100 can be secured to the patient without the retainer body 110 penetrating through the dermal layers 36 of the patient, and without necessarily requiring sutures or adhesive tapes bonded to the skin 30.

As described in more detail below in connection with FIGS. 4-8, the anchor device 100 can be installed into a skin penetration point 32 in accordance with a technique that reduces or eliminates the need to shift the subcutaneous tines 145 a-b of the anchors 140 a-b to or from a flexed or stressed configuration. As such, the anchor tines 145 a-b need not undergo substantial flexing during installation or removal. In these circumstances, the subcutaneous anchors may be both installed and removed from the skin penetration point 32 advantageously without the need for an external actuator handle or delivery device to deploy the subcutaneous tines 145 a-b. It should be understood that, in alternative embodiments, the anchor tines 145 a-b may be flexed to a different shape during installation or removal.

Still referring to FIG. 1, after installation of the subcutaneous anchor tines 145 a-b into the subcutaneous layer 34, the retainer body 110 and the adhesive fabric 170 can receive the medical instrument 102. In this embodiment, the adhesive fabric 170 receives the medical instrument 102 after a release liner 174 is removed from the adhesive fabric 170 to expose an adhesive layer 172 (FIGS. 2A-C). The release liner 174 may be removed before installation of the subcutaneous tines 145 a-b through the skin opening 32 or after installation of the subcutaneous tines 145 a-b through the skin opening 32. The medical instrument 102 may be placed in contact with the exposed adhesive fabric 170, and a user may fold the adhesive fabric 170 over the medical instrument 102 to secure the medical instrument 102 to the anchor device 100.

Accordingly, in some embodiments, the anchor device 100 can provide a capless design in which the anchor device 100 adhesively couples with an external portion of the medical instrument 102 without the need for attaching a cap or other similar component onto the retainer body 110, thereby simplifying the process of inspecting and cleaning the anchor device 100 and the skin surface near the skin penetration point 32 after installation. It should be understood that, in alternative embodiments, the retainer body 110 can be configured so as to mate with a cap component so as to supplement the holding force upon the medical instrument beyond the holding force provided from the adhesive fabric 170.

In the depicted example, the medical instrument 102 is embodied as a catheter. Hence, hereinafter the medical instrument 102 may alternatively be referred to as catheter 102, without limiting the medical instrument 102 to such an embodiment. In this embodiment, the example catheter 102 generally includes a proximal portion 26, a central portion 22, and a distal portion 28. The central portion 22 can interconnect the proximal portion 26 with the distal portion 28. In some embodiments, the proximal portion 26 of the catheter 102 may have multiple lumens (not shown) that are suited to deliver multiple types of solutions to the patient. In some embodiments, the catheter 102 includes a hub (e.g., hub 42 as described with respect to FIGS. 9-16) that can receive the multiple lumens on the proximal end of the hub, and merge the multiple lumens so as to connect with a single shaft of the distal portion 28.

Referring now to FIGS. 2A-2B, some embodiments of the anchor device 100 include the retainer body 110 and the anchors 140 a-b, which are connected to and extend distally from the distal end of the retainer body 110. For example, the anchors 140 a and 140 b can be connected to the retainer body 110 using an over-molding process to secure the anchors 140 a-b relative to the retainer body 110. It should also be understood that there exist many manufacturing processes that can secure the anchors 140 a and 140 b to the retainer body 110. In some embodiments, the retainer body 110 and the anchors 140 a and 140 b can be manufactured as a single, unitary piece.

In particular embodiments, the anchor device 100 can be configured to be folded longitudinally about a longitudinal fold axis 160 (e.g., a longitudinally extending region configured for enabling the retainer body 110 to repeatedly adjust from a first position to a second, folded position as shown, for example, in FIGS. 3A-3B). Consequently, the retainer body 110 can be described as having a first retainer body portion 120 a and a second retainer body portion 120 b. In some embodiments, the first and second retainer body portions 120 a-b can be substantially mirror images of each other. In alternative embodiments, the first and second portions of the anchor device 100 can be asymmetrical.

Preferably, at least a portion of each anchor 140 a-b comprises a flexible material. In some embodiments, the anchors 140 a-b may comprise a material that exhibits superelasticity. In some embodiments, at least a portion of the anchors 140 a-b (including the tines 145 a-b) may be formed from a length of nitinol wire or from a sheet of nitinol material. Alternatively, the anchors 140 a-b may comprise a metal material such as stainless steel (e.g., 304 stainless, 316 stainless, custom 465 stainless, and the like), spring steel, titanium, MP35N, and other cobalt alloys, or the like. In another alternative, the anchors 140 a-b may be formed from a resilient polymer material. In some embodiments, the anchors 140 a-b can be formed from a material or materials that allow the tines 145 a-b to be flexed and resiliently return to an unstressed position.

In the embodiment depicted in FIGS. 2A-C, each of the anchors 140 a-b may be designed such that the tines 145 a-b have an unstressed position wherein the tines 145 a-b have a convex curvature. The convex curvature shape of the tines 145 a-b may permit the tines 145 a-b to abut against the underside of the dermal layers 36 in a manner that reduces the likelihood of the tine tips 146 puncturing the underside of the dermal layers 36. Preferably, the tine tips 146 are rounded bulbs or otherwise non-sharp so as to further protect the underside of the dermal layers 36. In alternative embodiments, the tines 145 a-b may have a generally straight shape that extends substantially perpendicular to the longitudinal shaft portions of the anchors 140 a-b to the rounds tips 146.

The retainer body 110 can comprise one or more biocompatible polymer materials (e.g., PVC, polypropylene, polystyrene, or the like). In some embodiments, the retainer body 110 can comprise a combination of such materials, for example, when the flexible web portion comprises an elastically flexible silicone material while the first and second retainer body portions 120 a-b comprise a less flexible polymer material such as polypropylene, PVC, polystyrene, or the like. In some embodiments, the retainer body 110 can be formed using a molding process in which the retainer body 110 is over-molded around a portion of the anchors 140 a-b, especially in those embodiments in which the anchors 140 a-b comprise a metallic material. For example, the left retainer body portion 120 a can be over-molded around a portion of anchor 140 a and, during the same or a different molding process, the right body portion 120 b can be over-molded around a portion of anchor 140 b. Consequently, as described further below, when the retainer body 110 is folded, the respective anchors 140 a-b (being connected to the retainer body portions 120 a-b respectively) likewise move in conjunction with their respective retainer body portion 120 a-b.

Still referring to FIGS. 2A-C, the adhesive fabric 170 of the anchor device is optionally mounted to the retainer body 110 so that the adhesive fabric 170 extends proximally away from a proximal end of the retainer body 110 (e.g., extends away from the anchors 140 a-b). The adhesive fabric 170 may include a flexible substrate 175 on which an adhesive layer 172 has been formed (see FIG. 2B). For example, the flexible substrate 175 may comprise a mesh material or flexible woven material. The anchor device 100 may be manufactured with a releasable liner 174 covering the adhesive layer 172 to preserve the adhesive characteristics and to limit exposure of the adhesive layer 172 to environmental contaminants prior to user removal of the releasable liner 174. In practice, a user may readily remove the releasable liner 174 from the adhesive fabric 170 after installation of the subcutaneous anchor tines 145 a-b into the subcutaneous layer 34. The user may thereafter place the catheter 102 in contact with the adhesive layer 172, and fold a portion of the adhesive fabric 170 over top of the catheter 102 and onto another portion of the adhesive fabric. In this way, the catheter 102 may be sandwiched between two portions of the adhesive fabric 170, securing the catheter 102 to the anchor device 100. Thus, although the adhesive layer 172 is employed to secure the catheter 102 to the anchor device 100, the catheter 102 is anchored to the skin 30 using the subcutaneous tine 145 a-b (without the need to apply an adhesive directly to the skin 30).

In some embodiments, the adhesive fabric 170 may include a tear strip 180 that extends in a generally longitudinal direction (e.g., generally parallel to the longitudinal fold axis 160 of the retainer body 110). The adhesive fabric may be adapted such that pulling the tear strip 180 results in the adhesive fabric 170 separating along an installation of the tear strip 180 in the adhesive fabric 170. Said another way, the tear strip 180 may be adapted to separate the adhesive fabric 170 into multiple portions as a result of a user pulling the tear strip 180 away from the adhesive fabric 170, for example, in a direction that is generally traverse to a plane of the adhesive fabric 170. The tear strip 180 may embody a continuous polymer thread that is located within one or more layers of the flexible substrate 175. Optionally, the flexible substrate 175 may be perforated along the location of the tear strip 180 to facilitate separation of the adhesive fabric 170 as a result of the user pulling the tear strip 180 away from the adhesive fabric 170. The tear strip 180 may be manufactured with sufficient tensile strength to remain intact as the user pulls the tear strip 180 away from the adhesive fabric 170, and as the adhesive fabric 170 is ripped into two portions through force applied to the adhesive fabric 170 by the tear strip 180.

In some embodiments, the tear strip 180 may include a protruding portion 182 that is adapted to be grasped by the user with an instrument or between the user's fingers. The protruding portion 182 may be a most-proximal portion of the anchor device 100. The tear strip 180 may be positioned in the adhesive fabric 170 such that the tear strip 180 is located generally longitudinally along the catheter 102 when the adhesive fabric 170 is folded over the catheter 102. In this manner, after the catheter 102 has been secured to the anchor device 100, the practitioner is able to remove the catheter 102 from the anchor device 100 by pulling the tear strip 180 away from the adhesive fabric 170, separating the adhesive fabric 170 along a length of the catheter 102 and permitting removal of the catheter 102 through the separation in the adhesive fabric 170 while the adhesive fabric remains adhesively bonded to itself. The user may not grasp, for example, a corner of the adhesive fabric 170 and peel the corner of the adhesive fabric 170 off another portion of the adhesive fabric 170. Thus, after adhesive coupling of the catheter 102 to the anchor device 100, the catheter 102 may be removed in a straightforward manner from contact with the anchor device 100 and subcutaneous region 34 before the tines 145 a-b are removed from the subcutaneous region 34. Said another way, the anchor device 100 may be removed from the subcutaneous region 34 after catheter 102 has been removed from contact with the anchor device 100 and the subcutaneous region 34. The adhesive fabric 170 may remain folded over and adhesively bonded to itself (although separated into multiple portions) during removal of the anchor device 100 from the subcutaneous region 34.

The flexible substrate 175 of the adhesive fabric 170 can be manufactured from a flexible material such as a textile mesh, a polymer mesh, a polymer sheet, a flat web of polymer foam material, or a metallic foil. The adhesive layer 172 may comprise an adhesive, for example, a suitable medical adhesive. In some examples, a medical adhesive that is robust to cleaning agents and that provides a permanent hold may be employed as the adhesive layer 172. The releasable liner 174 may be formed of a polymer sheet or a wax paper, for example.

Still referring to FIGS. 2A-C, the adhesive fabric 170 can be configured to provide an effective coupling interface with the catheter 102 or other medical instrument, while providing features that simplify the overall use of the medical device anchor system 10. For example, in this embodiment, the adhesive fabric 170 may provide the user with a simplified coupling technique for mating the anchor device 100 to the catheter 102, and may furthermore do so without the need for an attachable cap device. In the depicted example, the adhesive fabric 170 in general is mounted to the retainer body 110, for example, so that the adhesive fabric may be folded along a fold axis 184 of the adhesive fabric 170 (e.g., a longitudinally extending region configured for the adhesive fabric 170 to fold upon itself). The fold axis 184 of the adhesive fabric 170 may be offset from but parallel to the longitudinal fold axis 160. The tear strip 180 may be located such that the tear strip 180 is substantially with the longitudinal fold axis 160 when the adhesive fabric 170 has been folded along the fold axis 184 (refer to FIG. 1). The tear strip 180 and the fold axis 184 of the adhesive fabric 170 can define borders between different regions of the adhesive fabric 170. Consequently, the adhesive fabric 170 can be described as having a first adhesive fabric portion 170 a, a second adhesive fabric portion 170 b, and third adhesive fabric portion 170 c.

The adhesive and flexible characteristics of the adhesive fabric 170 enables a user to fold the first adhesive fabric portion 170 a and the second adhesive portion 170 b into adhesive contact with both the catheter 102 and the third adhesive fabric portion 170 c. In this manner, the first adhesive fabric portion 170 a and the second adhesive fabric portion 170 b each adhere to both the catheter 102 and the third adhesive fabric portion 170 c. Furthermore, the third adhesive fabric portion 170 c may adhere with the catheter 102. Thus, when securing the medical device 102 to the retainer body 110, the user can place the catheter 102 in contact with the adhesive fabric 170, for example, along the longitudinal fold axis 160, and can thereafter fold the adhesive fabric 170 along the fold axis 184 (which may include a visual indicia of the fold axis 184, such as a solid or dotted line imprinted on the adhesive fabric 170). During the folding, the user may align the tear strip 180 with the catheter 102 and press the second adhesive fabric portion 170 b onto the catheter 102 and the third adhesive fabric portion 170 c, and can press the first adhesive fabric portion 170 a onto the catheter 102 and the third adhesive fabric portion 170 c. The contact of the catheter 102 with the first adhesive fabric portion 170 a, the second adhesive fabric portion 170 b, and the third adhesive fabric portion 170 c may result in a snug coupling of the catheter 102 to the anchor device 100.

In the embodiment shown in FIG. 2B, the adhesive fabric 170 is molded into a proximal portion of the retainer body 110 at junction 186, for example, with an insert molding operation. In another example, junction 186 may be a slot that is formed during a molding process, and the adhesive fabric 170 is bonded into the slot with a permanent adhesive during a manufacturing assembly process. In yet another example, the adhesive fabric 170 may be mechanically fastened into junction 186. In an alternative example, the adhesive fabric 170 may include a tongue portion that is mechanically fastened or permanently adhered to an underside of the retainer body 110 so that the adhesive fabric 170 extends proximally away from the proximal end of the retainer body 110.

As will be described further below, the adhesive coupling of the catheter 102 to the anchor device 100 generally restrains movement of the medical instrument 102 away from the skin penetration point 32. Further, the limited angular freedom of movement provided by the anchors 140 a-b permits the shaft of the catheter 102 to closely align with the skin penetration point 32 and reduce the stresses applied by the catheter 102 at the skin penetration point 32.

As shown in FIGS. 2A-B, some embodiments of the anchor device 100 also include a sloped nose region 130 along the retainer body 110. The sloped nose region 130 can be a generally planar surface near the distal end of the retainer body 110 that is oriented at a different angle than the generally planar surfaces of the first and second retainer body portions 120 a-b. The sloped nose region 130 can decline from the generally planar surfaces of the first and second retainer body portions 120 a-b such that the nose region 130 slopes downward in a distal direction towards longitudinal shafts 142 a-b of the anchors 140 a-b (e.g., and thus downward to the skin penetration point 32 when the anchor tines 145 a-b are deployed). The sloped nose region 130 can facilitate an orientation of the distal portion 28 of the medical instrument 102 that is directed toward the skin penetration point 32. In this manner, the stresses that can potentially be exerted on the skin 30 proximal to the skin penetration point 32 by the distal portion 28 of the medical instrument 102 can be reduced.

As shown in FIG. 2C, a flexible web portion 150 of the retainer body 110 can be positioned, for example, generally centrally between the first and second retainer body portions 120 a-b. As previously described, the flexible web portion 150 can extend longitudinally from a distal face of the retainer body 110 to a proximal face of the retainer body 110, and can be used to define the fold axis 160 about which the first and second retainer body portions 120 a-b are pivotable from the non-folded condition (FIG. 2A) to the folded condition (FIG. 3A). The flexible web portion 150 can comprise an elastically flexible biocompatible polymer material (e.g., silicon, PVC, polypropylene, polystyrene, or the like). In some embodiments, the flexible web portion 150 can be made of the same material as the other portions of the retainer body 110. In other embodiments, the flexible web portion 150 can be made of a different material than the other portions of the retainer body 110. In such a case, the anchor device 100 can be made, for example, using a two-step insert molding operation. The flexible web portion 150 can be biased to resiliently maintain the non-folded shape of the anchor device 100 as depicted in FIGS. 2A-2C. When the anchor device 100 is folded along the fold axis 160 due to a user's grasp (refer, for example, to FIG. 4), the flexible web portion 150 can undergo elastic deformation such that flexible web portion 150 biases the anchor device 100 to return the non-folded condition (FIGS. 2A and 5) upon release from the user. In addition or alternatively, the fabric 170 may also stretch along the longitudinal axis 160 and bias the anchor device 100 to return to the non-folded condition. In some embodiments, the fabric 170 may be two separate pieces of fabric that do not span the longitudinal fold axis 160, such that the two separate pieces of fabric are not stretched at a location of the longitudinal fold axis 160 when the anchor device is in the folded condition.

Referring now to FIGS. 3A-3B, in this example embodiment, the anchor device 100 may include features that allow the individual anchors 140 a-b to be moved relative to each other so as to facilitate both insertion and removal of the anchor device 100 through the skin penetration point 32. For example, the anchor device 100 may have a foldable configuration in which a first portion of the retainer body 110 is pivotably coupled via a flexible hinge portion to a second portion of the retainer body 110.

More specifically, in this embodiment, the first retainer body portion 120 a and the second retainer body portion 120 b can be flexibly pivoted with respect to each other along a fold axis 160 extending longitudinally through the retainer body 110. To initiate the folding process of the anchor device 100, the user can apply a bending moment about the fold axis 160 to the first and second retainer body portions 120 a-b. Such a bending moment can cause an elastic deformation of the flexible web portion 150 so as to fold the anchor device along the fold axis 160 (refer to FIG. 3A). Because the adhesive fabric portion 170 comprises the flexible substrate 175 and liner 174, the adhesive fabric portion 170 is sufficiently compliant to temporarily fold with the retainer body 110 during this operation. The first retainer body portion 120 a can be fixedly coupled to the anchor 140 a, and the second retainer body portion 120 b can be fixedly coupled to the anchor 140 b. Thus, as shown in FIG. 3A, when the first and second retainer body portions 120 a-b are pivoted about the fold axis 160, the two anchors 140 a-b likewise pivot relative to one another. This process of pivoting can cause the anchor device to transition from a non-folded condition (shown in FIGS. 2A-2C and in FIG. 1) in which the tines 145 a-b extend generally away from one another to a folded condition (shown in FIGS. 3A-3B), in which the tines 145 a-b are generally adjacent to each other and oriented to extend in substantially the same direction. Similarly, when the bending moment from the user is released, the anchor device can be biased to return the anchor device 100 from the folded condition to the non-folded condition. In the depicted embodiment, the tines 145 a-b can be rotated about 75-degrees to about 105-degrees, and preferably about 90-degrees, during the transition between the non-folded condition and the folded condition. As described in more detail below, the anchor device 100 can be arranged in the folded condition during both insertion and removal of the subcutaneous tines 145 a-b so as to reduce the likelihood of the tines 145 a-b causing damage to the skin 30.

Referring now to FIGS. 4-5, as previously described, the medical instrument 102 can optionally include a catheter to be inserted through the penetration point 32 of the skin 30 as part of a medical procedure. For example, in the embodiment depicted in FIG. 1, a central venous catheter 102 can be inserted into a percutaneous opening surgically formed in the skin (e.g., penetration point 32), to the underside of the skin 30, and into a vein 40 to provide vascular access for delivering medications or minimally invasive devices into a patient.

After placement of the catheter 102 through the penetration point 32 of the skin 30, the user can grasp the anchor device 100 in the folded condition and approach the penetration point 32 such that the free ends of the tines 145 a-b are contemporaneously inserted through the penetration point 32 while the tines 145 a-b are in a generally side-by-side condition (as depicted in FIG. 4). In particular embodiments, the subcutaneous tines 145 a-b are inserted through the skin penetration point 32 while the user conveniently grasps the retainer body 110 of the anchor device 100 and applies an insertion force until the convexly curved body portions of the subcutaneous tines 145 a-b are positioned below the surface of the skin 30 (while the remainder of the anchor device 100 resides external to the skin 30).

As the anchor device 100 is inserted through the penetration point 32, the tines 145 a-b are maintained in a generally non-stressed configuration (e.g., a first shape or a steady-state shape) while passing through the penetration point 32 in a manner that reduces the likelihood of trauma to the surrounding skin tissue 30. As the tines 145 a-b are collectively advanced through the penetration point 32, the free ends of the tines 145 a-b are moved beneath the dermal skin layers 36 of the skin 30.

When the tines 145 a-b reach the subcutaneous region 34, the retainer body 110 can adjusted to the unfolded condition so that the tines 145 a-b are shifted relative to one another, resulting in the tines 145 a-b extending outwardly away from one another (as depicted in FIG. 5). During that process of unfolding the retainer body 110, each tine 145 a-b may retain their generally non-stressed configuration (e.g., the first shape or the steady-state shape). Thus, the anchor device 100 can be installed in accordance with a technique that reduces or eliminates the need to shift the subcutaneous tines 145 a-b to or from a flexed or stressed configuration during the passage through the skin penetration point 32. Also, the adhesive fabric portion 170 of the anchor device 100 is sufficiently compliant to temporarily fold and unfolded with the retainer body 110 during this process.

As previously described, the anchor device 100 can secure the catheter 102 or other medical instrument relative to a skin penetration point 32. With the anchor device 100 positioned such that subcutaneous tines 145 a-b are in their deployed configuration, as shown in FIG. 5, the user may remove the releasable liner 174 of the adhesive fabric 170, exposing the adhesive layer 174 of the adhesive fabric 170. (Alternatively, the user may remove the releasable liner 174 before installation of the subcutaneous tines 145 a-b into the subcutaneous region 34.) After the releasable liner 174 has been removed, the previously inserted catheter 102 can be placed in contact with the adhesive layer 174 of the adhesive fabric 170. As shown in FIG. 5, the directional arrow 198 depicts an example motion of manually positioning the catheter 102 in contact with the adhesive fabric 170 to prepare for the coupling of the catheter 102 to the anchor device 100.

Referring now to FIGS. 6A-B, the catheter 102 can be placed in contact with the anchor device 100 so that the shaft of the catheter 102, for example, is generally aligned with the folding region 150 of the retainer body 110. In doing so, the catheter 102 is placed in contact with the adhesive layer 172 of the third portion 170 c (FIG. 2A) of the adhesive fabric 170, thereby temporarily retaining the catheter 102 is a position to receive the remaining portions 170 a-b of the adhesive fabric 170 over an upper side of the catheter 102. In order to adhesively couple the catheter 102 to the anchor device 102, the user may fold the adhesive fabric 170 (with the adhesive layer 172 exposed) along the fold axis 184 (FIG. 2A) and onto the catheter 102, aligning the tear strip 180 with the shaft of the catheter 102.

Referring now to FIGS. 7A-B, the anchor device of FIGS. 4-5 is adhesively coupled to the catheter 102. For example, the adhesive fabric 170 has been folded along the fold axis 184 over the catheter 102. The catheter 102 may be firmly secured between the upper and lower portions of adhesive fabric 170. In the embodiment shown in FIGS. 7A-B, the first adhesive fabric portion 170 a is in adhesive contact with the third adhesive fabric portion 170 c while the second adhesive fabric portion 170 b is in adhesive contact with the third adhesive fabric portion 170 c. The first adhesive fabric portion 170 a, the second adhesive fabric portion 170 b, and the third adhesive fabric portion 170 c may all contact the catheter 102. In this embodiment, the adhesive coupling of the catheter 102 to the anchor device 100 secures the catheter 102 to the anchor device along at least two regions of the catheter 102 that are on opposing sides of the catheter 102. With the adhesive fabric 170 folded over itself and adhesively secured to itself and the catheter 102, the catheter 102 is fixed to the anchor device 100.

FIG. 8 illustrates an example of removing of the catheter 102 (or other medical instrument) from the anchor device 100. In this example, the user can grasped the protruding portion 182 of the tear strip 180, and pull the protruding portion 182 away from the adhesive fabric 170, ripping the adhesive fabric 170 at the location of the tear strip 180 and permitting removal of the medical device 102 through the separation in the adhesive fabric 170. FIG. 8 shows the system 104 during removal of the tear strip 180 and ripping of the adhesive fabric 170, but it should be understood that the tear strip 180 may be completely removed from the adhesive fabric 170, resulting in a complete separation of the adhesive fabric 170, for example, along the previous location of the tear strip 180. It is after the complete separation of the adhesive fabric 170 that the catheter 102 may be removed from contact with the anchor device 100. In some examples, the catheter 102 is removed from contact with both the subcutaneous layer 34 and the anchor device before the subcutaneous tines 145 a-b are removed from the subcutaneous layer 34.

In some embodiments, some components of the system 104 can be provided in a sterilized kit that pairs a particular type of catheter 102 or other medical instrument with a corresponding anchor device 100. The particular type of catheter 102 or other medical instrument in the kit is compatible for adhesively mating with the anchor device 100 the kit. Each kit can include one or more anchor devices 100 and the particular type of catheter 102 or other medical instrument enclosed within a flexible packaging material, which preferably includes indicators that identify the type of catheter 102 or other medical instrument that is provided along with instructions for deploying and removing the anchor device 100. The kit may include a one-to-one ratio for the quantity of anchor devices 100 to the quantity of catheters 102. In other embodiments, the kit may include multiple anchor devices 100 (e.g., having differently sized or shaped tines 145 a-b) for each catheter 102 contained therein.

Alternatively, in some embodiments, the anchor device 100 can be provided in individual, sterilized packets so that a user can readily open such a packet and access the selected anchor device prior to insertion into the skin penetration point. Such individual packets can include a single anchor device enclosed within a flexible packaging material, which preferably includes indicators that identify the types of catheters or other medical instruments that are compatible for adhesively mating with the anchor device 100. As such, a user can readily select one of the packets for use after the type of catheter or medical instrument is selected for a particular patient.

FIGS. 9-16 show embodiments of a medical device anchor system 204 that is similar in some respects to the medical device anchor system 104. The medical device anchor system 204 includes an anchor device 200 that includes one or more adhesive fabric strips 270 a-b with multiple tear strips 280 a-b.

Referring to FIG. 9, some embodiments of the medical device anchor system 204 include an anchor device 200 that adhesively retains a medical instrument 202 in an operative position relative to a portion of skin 30. The medical instrument 202 can be adhesively coupled to the anchor device 200. The anchor device 200, in turn, can be coupled to the portion of skin 30. In this manner, the anchor device 200 can act as an intermediary member to cause the retention of the medical instrument 202 in a desired position with respect to the skin 30. The example embodiment of FIG. 9, can include a medical device 202 (e.g., a central venous catheter) inserted through a percutaneous opening formed in the skin (e.g., penetration point 32), proceeding to the underside of the skin 30, and into a vein 40 to provide vascular access for delivering medications, withdrawing fluids, or providing minimally invasive access into a patient.

In this example, the anchor device 200 can generally include a retainer body 210, adhesive fabric 270 a-b, and one or more anchors 240 a-b. The anchors 240 a-b extend distally from a distal end of the retainer body 210. As described further below, the anchor device 200 can be configured to couple with the medical instrument 202. The one or more anchors 240 a-b can be configured for deployment through a skin penetration point 32 and into a subcutaneous layer 34, so as to releasably retain the anchor device 200 with respect to the skin 30. For example, the anchor device 200 can include the one or more anchors 240 a and 240 b that extend distally from the retainer body 210 so as to penetrate through the same skin penetration point 32 while the retainer body 210 and the adhesive fabric 270 a-b remain external to the skin penetration point 32.

The anchors 240 a-b can include subcutaneous tines 245 a-b that, after insertion, reside in the subcutaneous region 34 so as to secure the position of the anchor device—and the medical instrument 202 retained therein—relative to the penetration point 32. When the tines 245 a-b are deployed in the subcutaneous region 34, the anchor device 200 can be secured to the patient without the retainer body 210 penetrating through the dermal layers 36 of the patient, and without necessarily requiring sutures or adhesive tapes bonded to the skin 30.

As described in more detail below in connection with FIGS. 12-16, the anchor device 200 can be installed into the skin penetration point 32 in accordance with a technique that reduces or eliminates the need to shift the subcutaneous anchors tines 245 a-b of the anchors 240 a-b to or from a flexed or stressed configuration. As such, the anchor tines 245 a-b need not undergo substantial flexing during installation or removal. In these circumstances, the subcutaneous anchors may be both installed and removed from the skin penetration point 32 advantageously without the need for an external actuator handle or delivery device to deploy the subcutaneous tines 245 a-b.

Still referring to FIG. 9, after installation of the subcutaneous anchor tines 245 a-b into the subcutaneous layer 34, the retainer body 210 and the adhesive fabric strips 270 a-b can receive the medical instrument 202. For the adhesive fabric strips 270 a-b to receive the medical instrument 202, a user may have removed releasable liners 274 a-b from the adhesive fabric strips 270 a-b to expose adhesive layers 272 a-b. The releasable liners 274 a-b may have been removed before installation of the subcutaneous tines 245 a-b or after installation of the subcutaneous tines 245 a-b. The medical instrument 202 may be placed in contact with the exposed adhesive fabric strips 270 a-b, and a user may fold the adhesive fabric strips 270 a-b over the medical instrument 202.

In this example, the medical instrument 202 is embodied as a catheter. Hence, hereinafter the medical instrument 202 may alternatively be referred to as catheter 202, without limiting the medical instrument 202 to such an embodiment. Furthermore, in some embodiments, the anchor device 200 can provide a capless design in which the anchor device 200 adhesively couples with an external portion of the catheter 202 without the need for attaching a cap onto the retainer body 210, thereby simplifying the process inspecting and cleaning the anchor device 200 and the skin surface near the skin penetration point 32 after installation.

In this embodiment, the example catheter 202 generally includes a proximal portion 46, a hub 42, and a distal portion 48. The hub 42 can interconnect the proximal portion 46 with the distal portion 48. In some embodiments, the proximal portion 46 of the catheter 202 may have multiple lumens that are suited to deliver multiple types of solutions to the patient. In some such embodiments, the hub 42 can receive the multiple lumens on the proximal end of the hub 42, and merge the multiple lumens so as to connect with a single lumen distal portion 48. For example, as shown in FIG. 9, the proximal portion 46 is depicted as having two lumens, and the distal portion 48 as having a single lumen that is adapted for percutaneous insertion through skin penetration point 32. Hence, the hub 42 can serve the purpose of merging multiple proximal supply lumens into a single distal delivery lumen suited for insertion into the patient.

The hub 42 can further be arranged to couple the catheter 202 onto the anchor device 200. In some embodiments, the hub 42 can include wings 24 a-b. The wings 24 a-b can have features that facilitate the coupling of the hub 42 to the anchor device 200. For example, the wings 24 a-b may be shaped to adhesively couple with the one or more adhesive fabric strips 270 a-b. As another example, some embodiments of the hub 42 can include apertures 47 a-b in the wings 24 a-b (see FIG. 13). The apertures 47 a-b can be located and sized to couple with corresponding features of anchor devices that may not include the adhesive fabric strips 270 a-b.

The hub 42 can be manufactured from an elastomeric or otherwise flexible material, such as silicone or another biocompatible polymer material (e.g., PVC, polypropylene, polystyrene, or the like). In some embodiments, the hub 42 can be made from a combination of materials. For example, at least wings 24 a-b may comprise silicone or another flexible biocompatible material so that the wings 24 a-b and the apertures 47 a-b can flexibly adjust to couple with the adhesive fabric strips 270 a-b or the above-described retention posts, whereas the portions of the hub 42 other than the wings 24 a-b may comprise a more rigid polymer material.

The anchor device 200 can be configured to adhesively couple to the catheter 202 through use of the multiple adhesive fabric strips 270 a-b. A user may wrap the adhesive fabric strips 270 a-b around the wings 24 a-b, respectively. The adhesive fabric strips 270 a-b may include backing layers 275 a-b on which adhesive layers 272 a-b have been formed (see FIG. 10C). The anchor device 200 may be manufactured so that releasable liners 274 a-b cover the adhesive layers 272 a-b to limit exposure of the adhesive layers 272 a-b to environmental contaminants and gases prior to user removal of the releasable liners 274 a-b. In practice, a user may remove the releasable liners 274 a-b from the adhesive fabric strips 270 a-b after installation of the subcutaneous anchor tines 245 a-b into the subcutaneous layer 34. The user may thereafter place the catheter 202 in contact with the retainer body 210, and fold portions of the adhesive fabric strips 270 a-b over top of the wings 24 a-b. In this way, the wings 24 a-b of the catheter 202 may be retained by at least portions of the adhesive fabric strips 270 a-b, securing the catheter 202 to the anchor device 200.

Each of the adhesive fabric strips 270 a-b may include a tear strip (e.g., tear strip 280 a or 280 b in the depicted embodiment). As discussed with respect to the adhesive fabric 270 of FIGS. 1-8, each of the adhesive fabric strips 270 a-b may be adapted such that pulling the respective tear strip 280 a or 280 b results in the adhesive fabric 270 a or 270 b separating along an installation of the tear strip 280 a or 280 b in the adhesive fabric 270 a or 270 b. The tear strips 270 a-b, backing layers 275 a-b, and adhesive layers 272 a-b may be constructed of the same materials and function similarly to the tear strip 170, flexible substrate 175, and adhesive layer 272 that are described with reference to FIGS. 1-8. The tear strips 280 a-b may include protruding portions 282 a-b that are adapted to be grasped by the user with an instrument or between the user's fingers.

The tear strips 280 a-b may be positioned in the adhesive fabric strips 270 a-b such that the tear strips 280 a-b generally run alongside surfaces 27 a-b when the adhesive fabric strips 270 a-b are folded over top surfaces 29 a-b of the wings 24 a-b. In this manner, after the catheter 202 has been secured to the anchor device 200, the user is able to remove the catheter 202 from the anchor device 200 by pulling the tear strips 280 a-b away from the adhesive fabric strips 270 a-b, separating the adhesive fabric strips 270 a-b along the locations of the side surfaces 27 a-b and permitting removal of the catheter 202, for example, without requiring the user to grasp corners of the adhesive fabric strips 270 a-b and peel the adhesive fabric strips 270 a-b off the wings 24 a-b. Indeed, portions of the adhesive fabric strips 270 a-b may remain adhesively bonded to the wings 24 a-b after removal of the catheter 202. Thus, after adhesive coupling of the catheter 202 to the anchor device 200, the catheter 202 may be removed in a straightforward manner from contact with the retainer body 210 and the subcutaneous region 34 before the tines 245 a-b are removed from the subcutaneous region 34. Said another way, the anchor device 200 may be removed from the subcutaneous region 34 after catheter 202 has been removed from contact with the anchor device 200 and the subcutaneous region 34 (except that the separated regions of the adhesive fabric strips 270 a-b may remain in contact with the wings 24 a-b after pulling of the tear strips 280 a-b).

Referring now to FIGS. 10A-B, some embodiments of the anchor device 200 include the retainer body 210 and the anchors 240 a-b, which are connected to and extend distally from the distal end of the retainer body 210. For example, the anchors 240 a and 240 b can be connected to the retainer body 210 using an over-molding process to secure the anchors 240 a-b relative to the retainer body 210. It should also be understood that there exist many manufacturing processes that can secure the anchors 240 a and 240 b to the retainer body 210. In some embodiments, the retainer body 210 and the anchors 240 a and 240 b can be manufactured as a single, unitary piece.

In particular embodiments, the anchor device 200 can be configured to be folded longitudinally about a longitudinal fold axis 260 (e.g., a longitudinally extending region configured for enabling the retainer body 210 to repeatedly adjust from a first position to a second, folded position as shown, for example, in FIGS. 11A-11B). Consequently, the retainer body 210 can be described as having a first retainer body portion 220 a and a second retainer body portion 220 b. In some embodiments, the first and second retainer body portions 220 a-b can be substantially mirror images of each other. In alternative embodiments, the first and second portions of the anchor device 200 can be asymmetrical.

The composition and construction of the anchors 240 a-b may be the same as that of anchors 140 a-b, discussed with reference to FIGS. 1-8. For example, the anchors 240 a-b may comprise a material that exhibits superelasticity. Moreover, each of the anchors 240 a-b may be designed such that the tines 245 a-b have an unstressed position wherein the tines 245 a-b have a convex curvature with tine tips 246 that are bulbs. The composition of the retainer body 210 and the connection of the retainer body 210 to the anchors 240 a-b may be the same as that of the retainer body 110 and the anchors 140 a-b.

Still referring to FIGS. 10A-C, the retainer body 210 can include first and second retainer body portions 220 a-b arranged on opposing sides of the longitudinal fold axis 260, left and right tabs 222 a-b, and (optionally) a sloped nose region 230. The first and second retainer body portions 220 a-b can be connected to each other at an elastically flexible web portion 150, which may be employed to define the fold axis 260.

Still referring to FIGS. 10A-C, the adhesive fabric strips 270 a-b can be configured to provide an effective coupling interface with the catheter 202 or other medical instrument, while providing features that simplify the overall use of the medical device anchor system 204. For example, in this embodiment, the adhesive fabric strips 270 a-b may provide the user with a simplified coupling technique for mating the anchor device 200 to the catheter 202, and may furthermore do so without the need for an attachable cap device or skin sutures. In the depicted example, the adhesive fabric strips 270 a-b in general are sized and attached the retainer body 210, for example, so that the adhesive fabric strips 270 a-b may be folded along fold axes 284 a-b of the adhesive fabric strips 270 a-b. The fold axes 284 a-b of the adhesive fabric 270 may be offset from but parallel to the longitudinal fold axis 260. The tear strips 280 may be located along the fold axes 284 a-b. The tear strips 280 a-b of the adhesive fabric strips 270 a-b can define borders between different regions of the adhesive fabric strips 270 a-b. Consequently, adhesive fabric 270 a can be described as having a first adhesive fabric portion 270 c and a second adhesive fabric portion 270 d, and the adhesive fabric 270 b can be described as having a first adhesive fabric portion 270 e and a second adhesive fabric portion 270 f. The fold axes 284 a-b may be defined along the tear strips 280 a-b.

The adhesive and flexible characteristics of the adhesive fabric strips 270 a-b enable a user to fold the first adhesive fabric portions 270 c and 270 e onto the top surfaces 29 a-b of the wings 24 a-b. In this manner, the first adhesive fabric portions 270 c and 270 e adhere to the top surfaces 29 a-b of the wings 24 a-b of the catheter 210. Furthermore, second adhesive fabric portions 270 d and 270 f may adhere to bottom surfaces 31 a-b of the wings 24 a-b. Thus, when securing the medical device 202 to the retainer body 210, the user can place the medical device 202 in contact with at least one of the second adhesive fabric portions 270 d and 270 f, and can thereafter fold the adhesive fabric strips 270 a-b along the fold axes 284 a-b (which may include a visual indicia of the fold axes 284 a-b, such as solid or dotted lines imprinted on the adhesive fabric strips 270 a-b). During the folding, the user may press the first adhesive fabric portions 270 c and 270 e onto the top surfaces 29 a-b of the wings 24 a-b. The contact of the wings 24 a-b with the adhesive fabric strips 270 a-b may result in a snug coupling of the catheter 202 to the retainer body 210.

In the embodiment shown in FIG. 10B, the adhesive fabric strips 270 a-b are bonded to outer surfaces of the retainer body 210, for example with a medical adhesive. In other embodiments (not shown), the adhesive fabric strips 270 a-b are molded into the retainer body 210 at junctions, for example, slots in the retainer body 210 with an insert molding operation. The adhesive fabric strips 270 a-b may be mechanically latched into junction 270. It should also be understood that there exist many manufacturing processes that can secure the adhesive fabric strips 270 a-b to the retainer body 210.

As will be described further below in reference to FIG. 14, the flexibility of the wings 24 a-b can allow some limited angular freedom of movement between the hub 42 and the anchor device 200, while generally restraining movement of the catheter 202 away from the skin penetration point 32. Further, the limited angular freedom of movement permits the hub 42 of the catheter 202 to be slightly titled relative to the anchor device 200, thereby permitting the hub 202 and the distal portion 48 of the medical instrument to more closely align with the skin penetration point 32 and reduce the stresses applied by the catheter 202 at the skin penetration point 32.

Still referring to FIGS. 10A-C, the anchor device 200 further includes first and second tabs 222 a-b. The first and second tabs 222 a-b are configured to simplify the act of manipulating and folding the anchor device 200. For example, as described further in reference to FIGS. 11A-B, the user can adjust the first and second tabs 222 a-b in a pivoting motion toward one another, which readily enables the user to fold the anchor device 200 along the longitudinal fold axis 260. The first and second tabs 222 a-b are also configured to provide a u-shaped cutout region 265 between the first and second tabs 222 a-b. This u-shaped cutout region 265 can more readily provide visualization and access to the skin region under the retainer body 210 for inspection and cleaning of the skin 30 around the skin penetration point 32.

The anchor device 200 also includes a sloped nose region 230. The sloped nose region 230 can be a generally planar surface near the distal end of the retainer body 210 that is oriented at a different angle than the generally planar surfaces of the first and second retainer body portions 220 a-b. The sloped nose region 230 can decline from the generally planar surfaces of the first and second retainer body portions 220 a-b such that the nose region 230 slopes downward in a distal direction towards longitudinal shafts 242 a-b of the anchors 240 a-b (e.g., and thus downward to the skin penetration point 32 when the anchor tines 245 a-b are deployed). As will be described further in reference to FIG. 14, the sloped nose region 230 can facilitate an orientation of the distal portion 48 of the catheter 202 that is directed toward the skin penetration point 32. In this manner, the stresses that can potentially be exerted on the skin 30 proximal to the skin penetration point 32 by the distal portion 48 of the catheter 202 can be reduced.

As shown in FIG. 10C, the flexible web portion 250 of the anchor device 200 can be positioned, for example, generally centrally between the first and second retainer body portions 220 a-b. As previously described, the flexible web portion 250 can extend longitudinally from a distal face of the retainer body 210 to a proximal face of the retainer body 210, and can be used to define the fold axis 260 about which the first and second retainer body portions 220 a-b are pivotable from the non-folded condition (FIG. 10A) to the folded condition (FIG. 11A). The left and right retainer body portions 220 a-b can be connected to opposing sides of the flexible web portion 250. The flexible web portion 250 can comprise an elastically flexible biocompatible polymer material, as discussed with reference to FIG. 2C. The flexible web portion 250 can be biased to resiliently maintain the non-folded shape of the anchor device 200 as depicted in FIGS. 10A-10C. When the anchor device 200 is folded along the fold axis 260 due to a user's grasp (refer, for example to FIG. 4), the flexible web portion 250 can undergo elastic deformation such that flexible web portion 250 biases the anchor device 200 to return the non-folded condition (FIGS. 2A and 5) upon release from the user. In some embodiments, the adhesive fabric strips 270 a-b comprise a single fabric that is joined across the fold axis 260. The single fabric may stretch and bias the anchor device 200 to the non-folded condition.

Referring now to FIGS. 11A-11B, in this example embodiment, the anchor device 200 may include features that allow the individual anchors 240 a-b to be moved relative to each other so as to facilitate both insertion and removal of the anchor device 200 through the skin penetration point 32, for example, as discussed with reference to FIGS. 3A-3B in regard to anchor device 100 and individual anchors 140 a-b.

Referring now to FIGS. 12-13, in some embodiments, the catheter 202 can include a catheter to be inserted through the penetration point 32 of the skin 30 as part of a medical procedure. After placement of the catheter 202 through the penetration point 32 of the skin 30, the user can grasp the anchor device 200 in the folded condition and approach the penetration point 32 such that the free ends of the tines 245 a-b are contemporaneously inserted through the penetration point 32 while the tines 245 a-b are in a generally side-by-side condition (as depicted in FIG. 12). In particular embodiments, the subcutaneous tines 245 a-b are inserted through the skin penetration point 32 while the user conveniently grasps the tabs 222 a-b of the retainer body 210 of the anchor device 200 and applies an insertion force until the convexly curved body portions of the subcutaneous tines 245 a-b are positioned below the surface of the skin 30 (while the remainder of the anchor device 200 resides external to the skin 30).

As the anchor device 200 is inserted through the penetration point 32, the tines 245 a-b are maintained in a generally non-stressed configuration (e.g., a first shape or a steady-state shape) while passing through the penetration point 32 in a manner that reduces the likelihood of trauma to the surrounding skin tissue 30. As the tines 245 a-b are collectively advanced through the penetration point 32, the free ends of the tines 245 a-b are moved beneath the dermal skin layers 36 of the skin 30.

When the tines 245 a-b reach the subcutaneous region 34, the retainer body 210 can adjusted to the unfolded condition so that the tines 245 a-b are shifted relative to one another, resulting in the tines 245 a-b extending outwardly away from one another (as depicted in FIG. 13). During that process of unfolding the retainer body 210, each tine 245 a-b may retain their generally non-stressed configuration (e.g., the first shape or the steady-state shape). Thus, the anchor device 200 can be installed in accordance with a technique that reduces or eliminates the need to shift the subcutaneous anchors tines 245 a-b to or from a flexed or stressed configuration during the passage through the skin penetration point 32. As such, the subcutaneous anchors tines 245 a-b need not undergo substantial flexing during installation or removal, and in some embodiments, the subcutaneous anchors tines 245 a-b can comprise a generally less costly material (such as stainless steel or biocompatible polymers) rather than more costly materials required for superelastic flexing.

As previously described, the anchor device 200 can secure the catheter 202 relative to a skin penetration point 32. With the anchor device 200 positioned such that subcutaneous anchors tines 245 a-b are in their deployed configuration, as shown in FIG. 13, the user may remove the releasable liners 274 a-b of the adhesive fabric strips 270 a-b, exposing the adhesive layers 274 a-b. (Alternatively, the user may remove the releasable liners 274 a-b before installation of the subcutaneous tines 245 a-b into the subcutaneous region 34.) After the releasable liners 274 a-b have been removed, the previously inserted catheter 202 can be placed in contact with the anchor device 200. As shown in FIG. 13, the directional arrow 298 depicts an example motion of manually positioning the catheter 202 in contact with the anchor device 200 to prepare for the coupling of the catheter 202 to the anchor device 200.

Referring now to FIG. 14, the hub 42 of the catheter 202 can be placed in contact with the anchor device 200 so that the wings 24 a-b of the hub 42 are, for example, generally aligned with the corresponding adhesive fabric strips 270 a-b. In doing so, the wings 24 a-b are placed in contact with the adhesive layer 272 of corresponding adhesive fabric strip 270 a-b, thereby temporarily retaining the catheter 202 is a position to receive the remaining portions of the adhesive fabric strips 270 a-b over an upper side of the wings 24 a-b. In order to adhesively couple the catheter 202 to the anchor device 202, the user may fold the adhesive fabric strips 270 a-b (with the adhesive layer 272 exposed) along the fold axes 284 a-b and onto the wings 24 a-b, preferably aligning the tear strips 280 a-b along the side surfaces 27 a-b.

Referring now to FIG. 15, the medical device anchor system 204 of FIGS. 12-13 is adhesively coupled to the medical instrument 202. For example, the adhesive fabric strips 270 a-b can be folded along the fold axes 284 a-b and onto the top surfaces 29 a-b. In the embodiment shown in FIG. 15, the first adhesive fabric portion 270 c is in contact with the top surface 29 a and the first adhesive fabric portion 270 e is in contact with the top surface 29 b. The second adhesive fabric portion 270 d may be in contact with the bottom surface 31 a and the second adhesive fabric portion 270 e may be in contact with the bottom surface 31 b. With the adhesive fabric strips 270 a-b folded onto the wings 24 a-b and adhesively bonded to the top surfaces 29 a-b of the wings 24 a-b, the catheter 202 is fixed to the anchor device 200.

As shown in FIG. 15, the anchor device 200 adhesively retains the medical instrument 202 (e.g., catheter) in an operative position relative to a portion of skin 30 (e.g., the skin penetration point 32). The medical instrument 202 is adhesively coupled to the anchor device 200, as described above. The anchor device 200, in turn, is coupled to the portion of skin 30, as described above. In such embodiments, the anchor device 200 can be secured to the patient without necessarily requiring sutures or adhesive tapes bonded to the skin 30. A distal portion 48 of the catheter 202 penetrates a skin penetration point 32 and distally extends into the subcutaneous layer 34. In this view, it can be seen that some embodiments of the system 204 can enable the distal end of the hub 42 to be positioned closely to the skin penetration point 32. Such a configuration provides a compact anchor system 204 that is convenient to install and maintain. This configuration can minimize the lengths of the tubing proximal to the patient, and reduce the need for securement of such tubing or other portions of the medical instrument 202 to the patient using tapes, adhesive dressings, and the like.

It can also be seen in FIG. 15 that the hub 42 of the catheter 202 may optionally inclined at an angle in relation to the skin surface 30. Such an orientation between the hub 42 and the skin 30 may, in some circumstances, reduce the stresses applied to the skin penetration point 32 of the patient by the distal portion 48 of the catheter 202. In particular, the example orientation depicted in FIG. 15 enables the distal portion 48 to be inclined at an angle in relation to the skin surface 30 which can thereby reduce the need for the distal portion 48 of the catheter 202 to have a significant bend at the skin penetration point.

FIG. 16 illustrates an example of removing of the catheter 202 from the anchor device 200. In this example, the user has grasped the protruding portions 282 a of the tear strips 280 a, and pulled the protruding portion 282 a away from the retainer body 210, ripping the adhesive fabrics 270 a at the location of the tear strip 180 a and permitting removal of the medical device 202 due to separation in the adhesive fabrics 270 a. FIG. 16 shows the system 204 during removal of the tear strips 280 a and ripping of the adhesive fabrics 270 a, but it should be understood that both tear strips 280 a-b may be completely removed from the adhesive fabric strips 270 a-b, resulting in a complete separation of both adhesive fabric strips 270 a-b, for example, along the fold axes 284 a-b. It is after the complete separation of the adhesive fabric strips 270 a-b that the catheter 202 may be removed from contact with the retainer body 210. In some examples, the catheter 202 is removed from contact with both the retainer body 210 and the subcutaneous layer 34 before the subcutaneous tines 245 a-b are removed from the subcutaneous layer 34.

In some embodiments, some components of the system 204 can be provided in a sterilized kit that pairs a particular type of catheter 202 or other medical instrument with a corresponding anchor device 200. The particular type of catheter 202 or other medical instrument in the kit is compatible for adhesively mating with the anchor device 200 in the kit. Each kit can include one or more anchor devices 200 and the particular type of catheter 202 or other medical instrument enclosed within a flexible packaging material, which preferably includes indicators that identify the type of catheter 202 or other medical instrument that is provided along with instructions for deploying and removing the anchor device 200. The kit may include a one-to-one ratio for the quantity of anchor devices 200 to the quantity of catheters 202. In other embodiments, the kit may include multiple anchor devices 200 (e.g., having differently sized or shaped tines 245 a-b) for each catheter 202 contained therein.

Alternatively, in some embodiments, the anchor device 200 can be provided in individual, sterilized packets so that a user can readily open such a packet and access the selected anchor device prior to insertion into the skin penetration point. Such individual packets can include a single anchor device enclosed within a flexible packaging material, which preferably includes indicators that identify the types of catheters or other medical instruments that are compatible for adhesively mating with the anchor device 200. As such, a user can readily select one of the packets for use after the type of catheter or medical instrument is selected for a particular patient.

Referring to now FIGS. 17A-B, some embodiments of the medical device anchor system include an anchor device 300 that adhesively retains a medical instrument (e.g., a catheter 102 as shown in FIG. 1, or the like) in an operative position relative to a portion of skin. Similar to the embodiments previously described in connection with FIGS. 1-8, the anchor device 300 can act as an intermediary member to cause the retention of the medical instrument in a desired position with respect to the skin 30. In this example, the anchor device 300 can generally include a retainer body 310 (including first and second portions 320 a-b), a flexible adhesive web 370, and one or more anchors 340 a-b. The anchor device 300 is similar to the embodiments previously described in connection with FIGS. 1-8, except that flexible adhesive web 370 is disposed along an underside of the retainer body 310. For example, the retainer body 310 can include two separate portions 320 a-b that are affixed to a designated region of the flexible adhesive web 370 (refer to FIG. 17A), and the longitudinal fold region 360 is defined by a small portion of the flexible adhesive web 370 positioned between opposing edges of the spate body portions 320 a-b. In this example, the flexible adhesive web 370 can serve both as the longitudinal hinge portion (e.g., that defines a longitudinal fold line for the retainer body 310) and as the securement structure for the medical instrument. Optionally, during manufacture of the anchor device 300, the two individual body portions 320 a-b (each having a corresponding anchor 340 a-b extending distally therefrom) can be bonded to an exposed region of an adhesive layer of the underlying flexible adhesive web 370. The proximal regions 370 a-c of the flexible adhesive web 370 may be equipped with a release liner 374 so as to preserve the portion of the adhesive layer 372 until the proximal regions 370 a-c are used to adhere to the catheter or other medical instrument.

Similar to the anchors 140 a-b previously described in connection with FIGS. 1-8, the anchors 340 a-b extend distally from a distal end of the retainer body 310 for deployment through a skin penetration point and into a subcutaneous layer, so as to releasably retain the anchor device 300 with respect to the skin. As such, the anchor device 300 can include the one or more anchors 340 a and 340 b that extend distally from the retainer body 310 so as to penetrate through the same skin penetration point while the retainer body 310 and the flexible adhesive web 370 remain external to the skin penetration point. Also similar to the anchors 140 a-b previously described in connection with FIGS. 1-8, the anchors 340 a-b can include longitudinal shaft portions 342 a-b that extend distally to corresponding subcutaneous tines 345 a-b. After insertion of the tines 345 a-b, the tines 345 a-b, reside in the subcutaneous region so as to secure the position of the anchor device 300—and the medical instrument retained thereto—relative to the penetration point. When the tines 345 a-b are deployed in the subcutaneous region, the anchor device 300 can be secured to the patient without the retainer body 310 penetrating through the dermal layers of the patient, and without necessarily requiring sutures or adhesive tapes bonded to the skin. As previously described, the anchor device 300 can be installed into the skin penetration point in accordance with a technique that reduces or eliminates the need to shift the subcutaneous anchors tines 345 a-b of the anchors 340 a-b to or from a flexed or stressed configuration. As such, the anchor tines 345 a-b may not necessarily undergo substantial flexing during installation or removal. In these circumstances, the subcutaneous anchors may be both installed and removed from the skin penetration point advantageously without the need for an external actuator handle or delivery device to deploy the subcutaneous tines 345 a-b.

Still referring to FIGS. 17A-B, after installation of the subcutaneous anchor tines 345 a-b into the subcutaneous layer, the retainer body 310 and the flexible adhesive web 370 can receive the catheter or other medical instrument. For the flexible adhesive web 370 to receive the catheter, a user may have removed releasable liner 374 from the flexible adhesive web 370 to expose the adhesive layer 372. The catheter may be placed in contact with the exposed flexible adhesive web 370, and a user may fold the adhesive portions 370 a-b (e.g., along the fold axis 384) over the catheter and into engagement with the remaining portion 370 c.

Similar to the embodiments previously described in connection with FIGS. 1-8, the flexible adhesive web 370 may include a tear strip 380 that extends in a generally longitudinal direction (e.g., generally parallel to the longitudinal fold region 360 of the retainer body 310). The flexible adhesive web 370 may be adapted such that pulling the tear strip 380 results in the flexible adhesive web 370 separating along an installation of the tear strip 380 in the flexible adhesive web 370. The tear strip 380 may be manufactured with sufficient tensile strength to remain intact as the user pulls the tear strip 380 away from the flexible adhesive web 370, and as the flexible adhesive web 370 is ripped into two portions through force applied to the flexible adhesive web 370 by the tear strip 380. In some embodiments, the tear strip 380 may include a protruding portion 382 that is adapted to be grasped by the user with an instrument or between the user's fingers. Thus, after adhesive coupling of the catheter to the anchor device 300, the catheter may be removed in a straightforward manner from contact with the anchor device 300 and subcutaneous region before the tines 345 a-b are removed from the subcutaneous region.

The flexible substrate 375 of the flexible adhesive web 370 can be manufactured from a flexible material such as a textile mesh, a polymer mesh, a polymer sheet, a flat web of polymer foam material, or a metallic foil. Preferably, the flexible substrate 375 is selected with the material and thickness sufficient to bias the retainer body 310 to the deployed configuration (as shown in FIG. 17A) after being temporarily adjusted to a folded condition (e.g., fold about the longitudinal fold region 360). The adhesive layer 372 may comprise an adhesive, for example, a suitable medical adhesive. In some examples, a medical adhesive that is robust to cleaning agents and that provides a permanent hold may be employed as the adhesive layer 372. The releasable liner 374 may be formed of a polymer sheet or a wax paper, for example.

A number of embodiments of the invention have been described. Nevertheless, it will be understood that various modifications may be made without departing from the scope of the invention. Accordingly, other embodiments are within the scope of the following claims. 

What is claimed is:
 1. An anchor device for securing the position of a medical instrument, the anchor device comprising: a retainer body comprising a first body portion that is hingedly coupled to a second body portion about a longitudinal folding region; one or more flexible adhesive strips mounted to the retainer body and being configured to adhesively attach with one or more corresponding exterior surfaces of the medical instrument; and first and second anchors that extend distally from a distal end of the retainer body, each anchor comprising a flexible tine that is deployable in a subcutaneous region to secure the retainer body relative to a penetration point, the first anchor being coupled to the first body portion and the second anchor being coupled to the second body portion, wherein the first body portion of the retainer body is hingedly movable relative to the second body portion about the longitudinal folding region while the first and second body portions are hingedly coupled so that the first and second anchors are adjustable from a first configuration in which the flexible tines extend outwardly away from one another to a second configuration in which the flexible tines extend generally in the same direction; wherein the longitudinal folding region comprises a flexible web portion positioned generally centrally between the first and second body portions and extending longitudinally from the distal end of the retainer body to a proximal face of the retainer body, wherein the flexible web portion is configured to define a longitudinal fold axis along the longitudinal folding region, and the first body portion is hingedly movable relative to the second body portion about the longitudinal fold axis to adjust the first and second anchors between the first and second configurations; and wherein the one more flexible adhesive strips comprise a first adhesive strip configured to define an adhesive strip fold axis that is substantially parallel to and offset from the longitudinal fold axis of the flexible web portion, the first adhesive strip foldable upon itself about the adhesive strip fold axis.
 2. The anchor device of claim 1, wherein the one or more flexible adhesive strips each have a lateral width extending generally perpendicular to the longitudinal fold axis and a longitudinal length extending generally parallel to the longitudinal fold axis, wherein the lateral width of each respective flexible adhesive strip is substantially greater than the longitudinal length of the respective flexible adhesive strip.
 3. A system for securing the position of a medical instrument, the system comprising: a medical instrument comprising a distal portion configured to extend through a skin penetration point and into a body, and an external portion configured to reside outside the body when the distal portion extends through the skin penetration point; and an anchor device comprising; a retainer body comprising a first body portion that is pivotably coupled to a second body portion; one or more flexible adhesive strips mounted to the retainer body and being configured to adhesively attach with one or more surfaces of the external portion of the medical instrument; and first and second anchors that extend distally from a distal end of the retainer body, each anchor comprising a flexible tine that is deployable through the skin penetration point occupied by the medical instrument and into a subcutaneous region to secure the retainer body relative to the skin penetration point, the first anchor being coupled to the first body portion and the second anchor being coupled to the second body portion, wherein the first body portion of the retainer body is pivotable relative to the second body portion while the first and second body portions are pivotably coupled so that the first and second anchors are adjustable from one another from a first configuration to a second configuration, in which the flexible tines extend generally in the same direction; wherein the retainer body comprises a flexible web portion positioned generally centrally between the first and second body portions and extending longitudinally from the distal end of the retainer body to a proximal face of the retainer body, wherein the flexible web portion is configured to define a longitudinal fold axis, and the first body portion is pivotable relative to the second body portion about the longitudinal fold axis to adjust the first and second anchors between the first and second configurations; and wherein the one or more flexible adhesive strips comprises a single flexible adhesive strip extending proximally from a proximal end of the retainer body and extending away from the first and second anchors; and wherein the one more flexible adhesive strips comprise a first adhesive strip configured to define an adhesive strip fold axis that is substantially parallel to and offset from the longitudinal fold axis of the flexible web portion, the first adhesive strip foldable upon itself about the adhesive strip fold axis.
 4. The anchor device of claim 1, wherein the one or more flexible adhesive strips each comprise a flexible substrate carrying an adhesive layer along a major surface thereof and a releasable liner over the adhesive layer.
 5. The anchor device of claim 4, wherein the flexible substrate comprises at least one of a fabric mesh material, a polymer mesh material, and a polymer sheet material.
 6. The anchor device of claim 5, wherein the releasable liner comprises at least one of a polymer sheet material and wax paper material.
 7. The anchor device of claim 1, wherein the retainer body further comprises a sloped nose region that has a generally planar upper surface that is oriented at a decline angle extending distally from the first and second body portions.
 8. The system of claim 3, wherein the medical instrument comprises a catheter, and wherein the one or more flexible adhesive strips comprises an adhesive layer configured to bond with the one or more surfaces of the external portion of the catheter.
 9. The system of claim 3, wherein the one or more flexible adhesive strips each comprise a flexible substrate carrying an adhesive layer along a major surface thereof and a releasable liner over the adhesive layer.
 10. The system of claim 9, wherein the flexible substrate comprises at least one of a fabric mesh material, a polymer mesh material, and a polymer sheet material.
 11. The system of claim 10, wherein the releasable liner comprises at least one of a polymer sheet material and wax paper material.
 12. The system of claim 8, wherein the retainer body further comprises a sloped nose region that has a generally planar upper surface that is oriented at a decline angle extending distally from the first and second body portions.
 13. The system of claim 8, wherein the one or more flexible adhesive strips each have a lateral width extending generally perpendicular to the longitudinal fold axis and a longitudinal length extending generally parallel to the longitudinal fold axis, wherein the lateral width of each width of each respective flexible adhesive strip is substantially greater than the longitudinal length of the respective flexible adhesive strip.
 14. The system of claim 13, wherein at least one of the one or more flexible strips comprises a tear strip that extends generally parallel to the longitudinal fold axis of the retainer body configured to separate the flexible strip into multiple portions.
 15. The system of claim 14, wherein the tear strip is substantially aligned with the catheter when the adhesive layer is bonded to the catheter.
 16. A system for securing the position of a medical instrument, the system comprising: a medical instrument comprising a distal portion configured to extend through a skin penetration point and into a body, and an external portion configured to reside outside the body when the distal portion extends through the skin penetration point; and a retainer body comprising a first body portion that is hingedly coupled to a second body portion about a longitudinal folding region; one or more flexible adhesive strips mounted to the retainer body and being configured to adhesively attach with one or more corresponding exterior surfaces of the medical instrument; and first and second anchors that extend distally from a distal end of the retainer body, each anchor comprising a flexible tine that is deployable in a subcutaneous region to secure the retainer body relative to the skin penetration point, the first anchor being coupled to the first body portion and the second anchor being coupled to the second body portion, wherein the first body portion of the retainer body is hingedly movable relative to the second body portion about the longitudinal folding region while the first and second body portions are hingedly coupled so that the first and second anchors are adjustable from a first configuration in which the flexible tines extend outwardly away from one another to a second configuration in which the flexible tines extend generally in the same direction; and wherein the one or more flexible adhesive strips comprise a first adhesive strip configured to define an adhesive strip fold axis that is substantially parallel to and offset from the longitudinal folding region of the flexible web portion, the first adhesive strip foldable over the medical instrument about the adhesive strip fold axis.
 17. The system of claim 16, wherein the one or more flexible adhesive strips each have a lateral width extending generally perpendicular to the longitudinal folding region and a longitudinal length extending generally parallel to the longitudinal folding region, wherein the lateral width of each width of each respective flexible adhesive strip is substantially greater than the longitudinal length of the respective flexible adhesive strip.
 18. The system of claim 17, wherein the retainer body further comprises sloped nose region that has a generally planar upper surface that is oriented at a decline angle extending distally from generally planar surfaces of the first and second body portions.
 19. The system of claim 18, wherein the one or more flexible adhesive strips comprises a single flexible adhesive strip extending proximally from a proximal end of the retainer body and extending away from the first and second anchors. 